Abstract
With a wide range of satellite-derived vegetation bio-geophysical products now available to users, validation efforts are required to assess their accuracy and fitness for purpose. Substantial progress in the validation of such products has been made over the last two decades, but quantification of the uncertainties associated with in situ reference measurements is rarely performed, and the incorporation of uncertainties within upscaling procedures is cursory at best. Since current validation practices assume that reference data represent the truth, our ability to reliably demonstrate compliance with product uncertainty requirements through conformity testing is limited. The Fiducial Reference Measurements for Vegetation (FRM4VEG) project, initiated by the European Space Agency, is aiming to address this challenge by applying metrological principles to vegetation and surface reflectance product validation. Following FRM principles, and in accordance with the International Standards Organisation’s (ISO) Guide to the Expression of Uncertainty in Measurement (GUM), for the first time, we describe an end-to-end uncertainty evaluation framework for reference data of two key vegetation bio-geophysical variables: the fraction of absorbed photosynthetically active radiation (FAPAR) and canopy chlorophyll content (CCC). The process involves quantifying the uncertainties associated with individual in situ reference measurements and incorporating these uncertainties within the upscaling procedure (as well as those associated with the high-spatial-resolution imagery used for upscaling). The framework was demonstrated in two field campaigns covering agricultural crops (Las Tiesas–Barrax, Spain) and deciduous broadleaf forest (Wytham Woods, UK). Providing high-spatial-resolution reference maps with per-pixel uncertainty estimates, the framework is applicable to a range of other bio-geophysical variables including leaf area index (LAI), the fraction of vegetation cover (FCOVER), and canopy water content (CWC). The proposed procedures will facilitate conformity testing of moderate spatial resolution vegetation bio-geophysical products in future validation exercises.
Highlights
Providing global coverage and routine revisit capabilities, satellite Earth observation (EO) represents a convenient means of monitoring bio-geophysical variables that describe the status of the vegetated environment
As a result of their distinct bio-geophysical characteristics, the in situ reference measurements acquired during the FRM4VEG field campaigns varied substantially between the two study sites
Higher fraction of intercepted photosynthetically active radiation (FIPAR) values were experienced at Wytham Woods, where in situ measurements ranged from 0.00 to 0.98, but with a mean and median of 0.80 and 0.90, respectively
Summary
Providing global coverage and routine revisit capabilities, satellite Earth observation (EO) represents a convenient means of monitoring bio-geophysical variables that describe the status of the vegetated environment. A wide range of satellite-derived vegetation bio-geophysical products are available to users [1,2,3,4,5,6]. If they are to be quantifiably used in environmental and scientific applications, validation efforts are required to determine their accuracy and characterise their uncertainty (which defines the range of possible values an estimate could reasonably represent). By validating products against independent in situ reference measurements, users are better able to assess fitness for purpose for their specific application. Over the last two decades, substantial progress in the validation of vegetation bio-geophysical products has been made, including the development of standard in situ reference measurement datasets [9,10,11,12,13,14,15] and community-agreed best practices [16,17]
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